//
// ZoneMinder Image Class Interface, $Date$, $Revision$
// Copyright (C) 2001-2008 Philip Coombes
// 
// This program is free software; you can redistribute it and/or
// modify it under the terms of the GNU General Public License
// as published by the Free Software Foundation; either version 2
// of the License, or (at your option) any later version.
// 
// This program is distributed in the hope that it will be useful,
// but WITHOUT ANY WARRANTY; without even the implied warranty of
// MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
// GNU General Public License for more details.
// 
// You should have received a copy of the GNU General Public License
// along with this program; if not, write to the Free Software
// Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301 USA.
// 

#ifndef ZM_IMAGE_H
#define ZM_IMAGE_H

#include "zm_coord.h"
#include "zm_ffmpeg.h"
#include "zm_jpeg.h"
#include "zm_logger.h"
#include "zm_mem_utils.h"
#include "zm_rgb.h"

#if HAVE_ZLIB_H
#include <zlib.h>
#endif // HAVE_ZLIB_H

class Box;
class Image;
class Polygon;

#define ZM_BUFTYPE_DONTFREE 0
#define ZM_BUFTYPE_MALLOC 1 
#define ZM_BUFTYPE_NEW 2
#define ZM_BUFTYPE_AVMALLOC 3
#define ZM_BUFTYPE_ZM 4

typedef void (*blend_fptr_t)(const uint8_t*, const uint8_t*, uint8_t*, unsigned long, double);
typedef void (*delta_fptr_t)(const uint8_t*, const uint8_t*, uint8_t*, unsigned long);
typedef void (*convert_fptr_t)(const uint8_t*, uint8_t*, unsigned long);
typedef void (*deinterlace_4field_fptr_t)(uint8_t*, uint8_t*, unsigned int, unsigned int, unsigned int);
typedef void* (*imgbufcpy_fptr_t)(void*, const void*, size_t);

extern imgbufcpy_fptr_t fptr_imgbufcpy;

/* Should be called from Image class functions */
inline static uint8_t* AllocBuffer(size_t p_bufsize) {
	uint8_t* buffer = (uint8_t*)zm_mallocaligned(64, p_bufsize);
	if ( buffer == nullptr )
		Fatal("Memory allocation failed: %s", strerror(errno));
	
	return buffer;
}

inline static void DumpBuffer(uint8_t* buffer, int buffertype) {
	if ( buffer && (buffertype != ZM_BUFTYPE_DONTFREE) ) {
    if ( buffertype == ZM_BUFTYPE_ZM ) {
      zm_freealigned(buffer);
    } else if ( buffertype == ZM_BUFTYPE_MALLOC ) {
      free(buffer);
    } else if ( buffertype == ZM_BUFTYPE_NEW ) {
      delete buffer;
		/*else if(buffertype == ZM_BUFTYPE_AVMALLOC)
			av_free(buffer);
		*/
    } else {
      Error("Unknown buffer type in DumpBuffer(%d)", buffertype);
    } 
	}
}


//
// This is image class, and represents a frame captured from a 
// camera in raw form.
//
class Image {
  private:
    delta_fptr_t delta8_rgb;
    delta_fptr_t delta8_bgr;
    delta_fptr_t delta8_rgba;
    delta_fptr_t delta8_bgra;
    delta_fptr_t delta8_argb;
    delta_fptr_t delta8_abgr;
    delta_fptr_t delta8_gray8;

    // Per object function pointer that we can set once we know the image dimensions
    blend_fptr_t blend;

    void update_function_pointers();

protected:
    struct Edge {
      int min_y;
      int max_y;
      double min_x;
      double _1_m;

      static bool CompareYX(const Edge &e1, const Edge &e2) {
        if ( e1.min_y == e2.min_y )
          return e1.min_x < e2.min_x;
        else
          return e1.min_y < e2.min_y;
      }

      static bool CompareX(const Edge &e1, const Edge &e2) {
        return e1.min_x < e2.min_x;
      }
    };
	
	inline void DumpImgBuffer() {
		DumpBuffer(buffer, buffertype);
    buffertype = ZM_BUFTYPE_DONTFREE;
		buffer = nullptr;
		allocation = 0;
	}
	
	inline void AllocImgBuffer(size_t p_bufsize) {
		if ( buffer ) 
			DumpImgBuffer();
		
		buffer = AllocBuffer(p_bufsize);
		buffertype = ZM_BUFTYPE_ZM;
		allocation = p_bufsize;
	}

public:
	enum { ZM_CHAR_HEIGHT=11, ZM_CHAR_WIDTH=6 };
	enum { LINE_HEIGHT=ZM_CHAR_HEIGHT+0 };

protected:
	static bool initialised;
	static unsigned char *abs_table;
	static unsigned char *y_r_table;
	static unsigned char *y_g_table;
	static unsigned char *y_b_table;
	static jpeg_compress_struct *writejpg_ccinfo[101];
	static jpeg_compress_struct *encodejpg_ccinfo[101];
	static jpeg_decompress_struct *readjpg_dcinfo;
	static jpeg_decompress_struct *decodejpg_dcinfo;
	static struct zm_error_mgr jpg_err;

	unsigned int width;
	unsigned int linesize;
	unsigned int height;
	unsigned int pixels;
	unsigned int colours;
  unsigned int padding;
	unsigned int size;
	unsigned int subpixelorder;
	unsigned long allocation;
  _AVPIXELFORMAT      imagePixFormat;
	uint8_t *buffer;
	int buffertype; /* 0=not ours, no need to call free(), 1=malloc() buffer, 2=new buffer */
	int holdbuffer; /* Hold the buffer instead of replacing it with new one */
	char text[1024];

public:
	Image();
	explicit Image(const char *filename);
	Image(int p_width, int p_height, int p_colours, int p_subpixelorder, uint8_t *p_buffer=0, unsigned int padding=0);
	Image(int p_width, int p_linesize, int p_height, int p_colours, int p_subpixelorder, uint8_t *p_buffer=0, unsigned int padding=0);
	explicit Image(const Image &p_image);
  explicit Image(const AVFrame *frame);

	~Image();
	static void Initialise();
	static void Deinitialise();

	inline unsigned int Width() const { return width; }
	inline unsigned int LineSize() const { return linesize; }
	inline unsigned int Height() const { return height; }
	inline unsigned int Pixels() const { return pixels; }
	inline unsigned int Colours() const { return colours; }
	inline unsigned int SubpixelOrder() const { return subpixelorder; }
	inline unsigned int Size() const { return size; }

  inline AVPixelFormat AVPixFormat() {
    if ( colours == ZM_COLOUR_RGB32 ) {
      return AV_PIX_FMT_RGBA;
    } else if ( colours == ZM_COLOUR_RGB24 ) {
      if ( subpixelorder == ZM_SUBPIX_ORDER_BGR){
        return AV_PIX_FMT_BGR24;
      } else {
        return AV_PIX_FMT_RGB24;
      }
    } else if ( colours == ZM_COLOUR_GRAY8 ) {
      return AV_PIX_FMT_GRAY8;
    } else {
      Error("Unknown colours (%d)",colours);
      return AV_PIX_FMT_RGBA;
    }
  }
	
	/* Internal buffer should not be modified from functions outside of this class */
	inline const uint8_t* Buffer() const { return buffer; }
	inline const uint8_t* Buffer(unsigned int x, unsigned int y=0) const { return &buffer[(y*linesize)+x]; }
	/* Request writeable buffer */
	uint8_t* WriteBuffer(const unsigned int p_width, const unsigned int p_height, const unsigned int p_colours, const unsigned int p_subpixelorder);
  // Is only acceptable on a pre-allocated buffer
	uint8_t* WriteBuffer() { return holdbuffer ? buffer : nullptr; };
	
	inline int IsBufferHeld() const { return holdbuffer; }
	inline void HoldBuffer(int tohold) { holdbuffer = tohold; }
	
	inline void Empty() {
    if ( !holdbuffer )
      DumpImgBuffer();

    width = linesize = height = colours = size = pixels = subpixelorder = 0;
	}
	
	void Assign(
      unsigned int p_width,
      unsigned int p_height,
      unsigned int p_colours,
      unsigned int p_subpixelorder,
      const uint8_t* new_buffer,
      const size_t buffer_size);
	void Assign(const Image &image);
  void Assign(const AVFrame *frame);
	void AssignDirect(
      const unsigned int p_width,
      const unsigned int p_height,
      const unsigned int p_colours,
      const unsigned int p_subpixelorder,
      uint8_t *new_buffer,
      const size_t buffer_size,
      const int p_buffertype);

  int PopulateFrame(AVFrame *frame);

	inline void CopyBuffer(const Image &image) {
		Assign(image);
	}
	inline Image &operator=(const Image &image) {
		Assign(image);
		return *this;
	}
	inline Image &operator=(const unsigned char *new_buffer) {
		(*fptr_imgbufcpy)(buffer, new_buffer, size);
		return *this;
	}

	bool ReadRaw(const char *filename);
	bool WriteRaw(const char *filename) const;

	bool ReadJpeg(const char *filename, unsigned int p_colours, unsigned int p_subpixelorder);

	bool WriteJpeg(const char *filename) const;
	bool WriteJpeg(const char *filename, bool on_blocking_abort) const;	
  bool WriteJpeg(const char *filename, int quality_override) const;
  bool WriteJpeg(const char *filename, struct timeval timestamp) const;
  bool WriteJpeg(const char *filename, int quality_override, struct timeval timestamp) const;
  bool WriteJpeg(const char *filename, int quality_override, struct timeval timestamp, bool on_blocking_abort) const;
  
	bool DecodeJpeg(const JOCTET *inbuffer, int inbuffer_size, unsigned int p_colours, unsigned int p_subpixelorder);
	bool EncodeJpeg(JOCTET *outbuffer, int *outbuffer_size, int quality_override=0) const;

#if HAVE_ZLIB_H
	bool Unzip(const Bytef *inbuffer, unsigned long inbuffer_size);
	bool Zip(Bytef *outbuffer, unsigned long *outbuffer_size, int compression_level=Z_BEST_SPEED) const;
#endif // HAVE_ZLIB_H

	bool Crop(unsigned int lo_x, unsigned int lo_y, unsigned int hi_x, unsigned int hi_y);
	bool Crop(const Box &limits);

	void Overlay(const Image &image);
	void Overlay(const Image &image, unsigned int x, unsigned int y);
	void Blend(const Image &image, int transparency=12);
	static Image *Merge( unsigned int n_images, Image *images[] );
	static Image *Merge( unsigned int n_images, Image *images[], double weight );
	static Image *Highlight( unsigned int n_images, Image *images[], const Rgb threshold=RGB_BLACK, const Rgb ref_colour=RGB_RED );
	//Image *Delta( const Image &image ) const;
	void Delta( const Image &image, Image* targetimage) const;

	const Coord centreCoord(const char *text, const int size) const;
  void MaskPrivacy( const unsigned char *p_bitmask, const Rgb pixel_colour=0x00222222 );
	void Annotate( const char *p_text, const Coord &coord, const unsigned int size=1, const Rgb fg_colour=RGB_WHITE, const Rgb bg_colour=RGB_BLACK );
	Image *HighlightEdges( Rgb colour, unsigned int p_colours, unsigned int p_subpixelorder, const Box *limits=0 );
	//Image *HighlightEdges( Rgb colour, const Polygon &polygon );
	void Timestamp( const char *label, const time_t when, const Coord &coord, const int size );
	void Colourise(const unsigned int p_reqcolours, const unsigned int p_reqsubpixelorder);
	void DeColourise();

	void Clear() { memset( buffer, 0, size ); }
	void Fill( Rgb colour, const Box *limits=0 );
	void Fill( Rgb colour, int density, const Box *limits=0 );
	void Outline( Rgb colour, const Polygon &polygon );
	void Fill( Rgb colour, const Polygon &polygon );
	void Fill( Rgb colour, int density, const Polygon &polygon );

	void Rotate( int angle );
	void Flip( bool leftright );
	void Scale( unsigned int factor );

	void Deinterlace_Discard();
	void Deinterlace_Linear();
	void Deinterlace_Blend();
	void Deinterlace_Blend_CustomRatio(int divider);
	void Deinterlace_4Field(const Image* next_image, unsigned int threshold);
	
};

#endif // ZM_IMAGE_H

/* Blend functions */
void sse2_fastblend(const uint8_t* col1, const uint8_t* col2, uint8_t* result, unsigned long count, double blendpercent);
void std_fastblend(const uint8_t* col1, const uint8_t* col2, uint8_t* result, unsigned long count, double blendpercent);
void neon32_armv7_fastblend(const uint8_t* col1, const uint8_t* col2, uint8_t* result, unsigned long count, double blendpercent);
void neon64_armv8_fastblend(const uint8_t* col1, const uint8_t* col2, uint8_t* result, unsigned long count, double blendpercent);
void std_blend(const uint8_t* col1, const uint8_t* col2, uint8_t* result, unsigned long count, double blendpercent);

/* Delta functions */
void std_delta8_gray8(const uint8_t* col1, const uint8_t* col2, uint8_t* result, unsigned long count);
void std_delta8_rgb(const uint8_t* col1, const uint8_t* col2, uint8_t* result, unsigned long count);
void std_delta8_bgr(const uint8_t* col1, const uint8_t* col2, uint8_t* result, unsigned long count);
void std_delta8_rgba(const uint8_t* col1, const uint8_t* col2, uint8_t* result, unsigned long count);
void std_delta8_bgra(const uint8_t* col1, const uint8_t* col2, uint8_t* result, unsigned long count);
void std_delta8_argb(const uint8_t* col1, const uint8_t* col2, uint8_t* result, unsigned long count);
void std_delta8_abgr(const uint8_t* col1, const uint8_t* col2, uint8_t* result, unsigned long count);

void fast_delta8_gray8(const uint8_t* col1, const uint8_t* col2, uint8_t* result, unsigned long count);
void fast_delta8_rgb(const uint8_t* col1, const uint8_t* col2, uint8_t* result, unsigned long count);
void fast_delta8_bgr(const uint8_t* col1, const uint8_t* col2, uint8_t* result, unsigned long count);
void fast_delta8_rgba(const uint8_t* col1, const uint8_t* col2, uint8_t* result, unsigned long count);
void fast_delta8_bgra(const uint8_t* col1, const uint8_t* col2, uint8_t* result, unsigned long count);
void fast_delta8_argb(const uint8_t* col1, const uint8_t* col2, uint8_t* result, unsigned long count);
void fast_delta8_abgr(const uint8_t* col1, const uint8_t* col2, uint8_t* result, unsigned long count);

void neon32_armv7_delta8_gray8(const uint8_t* col1, const uint8_t* col2, uint8_t* result, unsigned long count);
void neon32_armv7_delta8_rgba(const uint8_t* col1, const uint8_t* col2, uint8_t* result, unsigned long count);
void neon32_armv7_delta8_bgra(const uint8_t* col1, const uint8_t* col2, uint8_t* result, unsigned long count);
void neon32_armv7_delta8_argb(const uint8_t* col1, const uint8_t* col2, uint8_t* result, unsigned long count);
void neon32_armv7_delta8_abgr(const uint8_t* col1, const uint8_t* col2, uint8_t* result, unsigned long count);
void neon64_armv8_delta8_gray8(const uint8_t* col1, const uint8_t* col2, uint8_t* result, unsigned long count);
void neon64_armv8_delta8_rgba(const uint8_t* col1, const uint8_t* col2, uint8_t* result, unsigned long count);
void neon64_armv8_delta8_bgra(const uint8_t* col1, const uint8_t* col2, uint8_t* result, unsigned long count);
void neon64_armv8_delta8_argb(const uint8_t* col1, const uint8_t* col2, uint8_t* result, unsigned long count);
void neon64_armv8_delta8_abgr(const uint8_t* col1, const uint8_t* col2, uint8_t* result, unsigned long count);
void sse2_delta8_gray8(const uint8_t* col1, const uint8_t* col2, uint8_t* result, unsigned long count);
void sse2_delta8_rgba(const uint8_t* col1, const uint8_t* col2, uint8_t* result, unsigned long count);
void sse2_delta8_bgra(const uint8_t* col1, const uint8_t* col2, uint8_t* result, unsigned long count);
void sse2_delta8_argb(const uint8_t* col1, const uint8_t* col2, uint8_t* result, unsigned long count);
void sse2_delta8_abgr(const uint8_t* col1, const uint8_t* col2, uint8_t* result, unsigned long count);
void ssse3_delta8_rgba(const uint8_t* col1, const uint8_t* col2, uint8_t* result, unsigned long count);
void ssse3_delta8_bgra(const uint8_t* col1, const uint8_t* col2, uint8_t* result, unsigned long count);
void ssse3_delta8_argb(const uint8_t* col1, const uint8_t* col2, uint8_t* result, unsigned long count);
void ssse3_delta8_abgr(const uint8_t* col1, const uint8_t* col2, uint8_t* result, unsigned long count);

/* Convert functions */
void std_convert_rgb_gray8(const uint8_t* col1, uint8_t* result, unsigned long count);
void std_convert_bgr_gray8(const uint8_t* col1, uint8_t* result, unsigned long count);
void std_convert_rgba_gray8(const uint8_t* col1, uint8_t* result, unsigned long count);
void std_convert_bgra_gray8(const uint8_t* col1, uint8_t* result, unsigned long count);
void std_convert_argb_gray8(const uint8_t* col1, uint8_t* result, unsigned long count);
void std_convert_abgr_gray8(const uint8_t* col1, uint8_t* result, unsigned long count);
void std_convert_yuyv_gray8(const uint8_t* col1, uint8_t* result, unsigned long count);

void fast_convert_rgb_gray8(const uint8_t* col1, uint8_t* result, unsigned long count);
void fast_convert_bgr_gray8(const uint8_t* col1, uint8_t* result, unsigned long count);
void fast_convert_rgba_gray8(const uint8_t* col1, uint8_t* result, unsigned long count);
void fast_convert_bgra_gray8(const uint8_t* col1, uint8_t* result, unsigned long count);
void fast_convert_argb_gray8(const uint8_t* col1, uint8_t* result, unsigned long count);
void fast_convert_abgr_gray8(const uint8_t* col1, uint8_t* result, unsigned long count);
void fast_convert_yuyv_gray8(const uint8_t* col1, uint8_t* result, unsigned long count);

void ssse3_convert_rgba_gray8(const uint8_t* col1, uint8_t* result, unsigned long count);
void ssse3_convert_bgra_gray8(const uint8_t* col1, uint8_t* result, unsigned long count);
void ssse3_convert_argb_gray8(const uint8_t* col1, uint8_t* result, unsigned long count);
void ssse3_convert_abgr_gray8(const uint8_t* col1, uint8_t* result, unsigned long count);
void ssse3_convert_yuyv_gray8(const uint8_t* col1, uint8_t* result, unsigned long count);
void zm_convert_yuyv_rgb(const uint8_t* col1, uint8_t* result, unsigned long count);
void zm_convert_yuyv_rgba(const uint8_t* col1, uint8_t* result, unsigned long count);
void zm_convert_rgb555_rgb(const uint8_t* col1, uint8_t* result, unsigned long count);
void zm_convert_rgb555_rgba(const uint8_t* col1, uint8_t* result, unsigned long count);
void zm_convert_rgb565_rgb(const uint8_t* col1, uint8_t* result, unsigned long count);
void zm_convert_rgb565_rgba(const uint8_t* col1, uint8_t* result, unsigned long count);

/* Deinterlace_4Field functions */
void std_deinterlace_4field_gray8(uint8_t* col1, uint8_t* col2, unsigned int threshold, unsigned int width, unsigned int height);
void std_deinterlace_4field_rgb(uint8_t* col1, uint8_t* col2, unsigned int threshold, unsigned int width, unsigned int height);
void std_deinterlace_4field_bgr(uint8_t* col1, uint8_t* col2, unsigned int threshold, unsigned int width, unsigned int height);
void std_deinterlace_4field_rgba(uint8_t* col1, uint8_t* col2, unsigned int threshold, unsigned int width, unsigned int height);
void std_deinterlace_4field_bgra(uint8_t* col1, uint8_t* col2, unsigned int threshold, unsigned int width, unsigned int height);
void std_deinterlace_4field_argb(uint8_t* col1, uint8_t* col2, unsigned int threshold, unsigned int width, unsigned int height);
void std_deinterlace_4field_abgr(uint8_t* col1, uint8_t* col2, unsigned int threshold, unsigned int width, unsigned int height);
